KR101684573B1 - Turbidity sensor for an electric household appliance - Google Patents

Abstract

An optical type turbidity sensor (1) comprises a casing (5) accommodating light emitting means (6) and light receiving means (8); The light emitting means 6 and the light receiving means 8 are arranged on the same side 10 of the casing, preferably under the transparent portion 15 of the same lens shape, (11) configured to receive a light ray (R1) from a light source (6) and reflect it towards the light receiving means (8), and being spaced from the reflective surface; The reflecting surface 11 is provided with means 18 for changing the distance D existing between the side surface 10 and the reflecting surface 11 of the casing in which the light emitting means 6 and the light receiving means 8 are arranged side by side ). ≪ / RTI >

Description

TECHNICAL FIELD [0001] The present invention relates to a turbidity sensor for an electric home appliance,

The present invention relates to an apparatus for measuring the optical absorbance of a liquid present in a tank of a household appliance such as a basket of a washing machine or a sump of a dishwasher while the household appliance is operating, And more particularly to an optical turbidity sensor for a washing machine or a dishwasher.

Optical type sensors are known from the patent document EP 1335060B1 and these sensors are able to detect the turbidity of the washing fluid of household appliances by measuring absorbance during use. This measurement is used by household appliances to confirm the correct operating performance of the established washing cycle and / or to adapt the cleaning strokes to the dirty condition of the washed dishes or laundry.

The known sensor has a fork shaped casing with two "fingers", the first finger receiving a photo emitting element at its tip and the second finger receiving a photo receiving element ), And a temperature sensor is also included in the longer "finger" (of the two). These two light emitting and light receiving elements thus allow the absorbance of the fluid to be measured between the two "fingers" so that the turbidity of the fluid itself can be assessed.

Known sensors have several drawbacks. First, its size is relatively large, especially in the landscape direction. Second, it does not allow any sensor readout correction, except for the electronic level, which uses, for example, a costly and complex solution, a microprocessor. Thirdly, the distance between the (optical) emitter and the (optical) receiver can be affected by variations in the "finger" that can occur during use, thereby degrading the accuracy of the sensor. Because of the prism shape of the casing, it is also complicated to assemble into household appliances.

It is an object of the present invention to overcome the shortcomings of the prior art and to provide a turbidity sensor having a small size, high reliability, high assembling easiness and high manufacturability, which can reduce costs and can be easily corrected.

Accordingly, the present invention relates to the turbidity sensor for household appliances as set forth in claim 1.

In particular, the sensor comprises a casing for receiving the light emitting means and the light receiving means; According to a principal aspect of the present invention, the light emitting means and the light receiving means are provided on the second side of the casing opposite the first side and are arranged to receive a light ray from the light emitting means and to reflect the light ray toward the light receiving means, And are arranged side by side on the same first side of the casing spaced therefrom.

According to another aspect of the present invention, the reflective surface is operatively coupled to a means, in particular a screw means, for changing the distance between the first side of the casing and the reflective surface in micrometers. Further, the light emitting means and the light receiving means are arranged below a transparent portion of the same lens shape on the first side of the casing.

In this regard, it has been found through experimentation that when absorbance readings are made by reflection, the absorbance readings are much more accurate than the "direct" readings done by the light receiver directly receiving the rays emitted from the light emitters. Also by changing the distance in micrometers between the reflective surface and the lens covering the light emitting and receiving diodes, which can be obtained simply and cost-effectively by fitting the reflective surface to a threaded shank, Correction can be made very simply. Another advantage is that all the electronic components are arranged adjacent to each other, so that these electronic components can be formed on a single printed circuit, which can also have a temperature detection element.

Finally, the casing can be fabricated to have an axially symmetrical structure by cup-shaped elements concentrically disposed on the sides of their respective recesses, thereby greatly reducing the dimensions of the sensor, Thereby facilitating the construction of the fluid-tight assembly in an operative seat formed therethrough.

Other features and advantages of the present invention will become apparent from the following description of the preferred embodiments given by way of non-limiting example with reference to the accompanying drawings.

As described above, the present invention has such effects as reducing the cost and correcting easily, and providing a turbidity sensor having smaller dimensions, high reliability, high assembling easiness and high manufacturability.

FIG. 1 is an isometric front perspective view showing a decomposition state of a turbidity sensor according to the present invention,
Figure 2 is a longitudinal sectional view of the sensor of Figure 1 in an assembled state.

1 and 2, reference numeral 1 generally refers to an optical type turbidity sensor for household appliances, particularly washing machines or dishwashers, and includes a through seat 4 for the sensor 1, And only the tank 3 filled with the operating liquid or the working fluid L of the household appliance in which the physical characteristics such as absorbance and temperature are to be measured is shown.

The sensor 1 comprises a light emitting means composed of a diode 6 and a casing 5 accommodating a light receiving means consisting of a separate diode 8.

According to one aspect of the present invention, the light emitting means 6 and the light receiving means 8 comprise a reflective surface 11 provided on the second side 12 of the casing 5 opposite the first side 10, And are arranged side by side on the same first side 10 of the casing 5 spaced therefrom. The reflective surface 11 is configured to receive a light ray R1 (e.g., light or infrared) from the light emitting means 6 and reflect it towards the light receiving means 8 with a reflected light ray R2.

In particular, the light emitting means 6 and the light receiving means 8 are arranged side by side under the same lens-shaped transparent portion 15 of the first side 10 of the casing 5.

According to another preferred embodiment of the present invention, the reflective surface 11 also includes means for changing the distance D between the first side 10 of the casing 5 and the reflective surface 11 in micrometers Lt; RTI ID = 0.0 > 18 < / RTI > As the reflective surface 11 is formed on one side of the disc 20 provided in the threaded shank 21, this means 18 is made of screw means and the threading shank 21 Is again engaged with a threaded seat 22 formed through the second side 12 of the casing 5.

According to another preferred embodiment of the present invention, the casing 5 comprises first and second cup-shaped elements, designated respectively as 30 and 31, with their respective recesses facing the same side, (30) is fitted concentrically within the cup-shaped element (31); The bottom wall 32 of the cup-shaped element 31 forms the first side 10 of the casing 5 by its first outer surface and the bottom wall 32 of the cup- At least a pair of opposing side members (not shown) having a cross member 42 forming a second side 12 of the casing 5 at a position spaced from the wall 32 at a position facing the bottom wall 41 are provided.

The diodes 6 and 8 are connected to the corresponding bottom wall 38 of the cup-shaped element 30 with the bottom wall 32 of the cup-shaped element 31 and the snap engagement support 39 for the printed circuit 5 On the same plane of the printed circuit 50 sandwiched between the printed circuit board 50 and the printed circuit board 50.

The cup-shaped elements 30 and 31 are made of synthetic plastic material and are integrally snapped together by their respective side walls 60 and 61; A connector 65 is also integrally formed within the recess of the first cup-shaped element 30 and is inserted into the printed circuit 50 in its appropriate perforation and mounted through the first cup- Is connected to the printed circuit 50 by a plurality of electrically conductive (conductive) shanks or rods (shanks or rods) 66.

Finally, according to another aspect of the present invention, a temperature detecting element 70 is further provided on the side of the light emitting means 6 and the light receiving means 8 on the side surface 10 of the casing 5. [ Particularly, the light emitting means 6, the light receiving means 8 and the temperature detecting element 70 are provided in the same printed circuit 50. The printed circuit 50 has a lens-shaped transparent portion 15, As shown in FIG.

Alternatively, according to a variant (not shown), a single diode may be used in place of the two individual diodes 6 and 8, in which case the diode is arranged on the side of the temperature sensing element 70, The diode operates as both a light emitter and an optical receiver; In this case the lens 15 should be made to focus the reflected ray R2 towards a single diode.

1: (turbidity) sensor 3: tank
4: through seat 5: casing
6: light emitting means (diode) 8: light receiving means (diode)
10: first side 11: reflective surface
12: second side 30, 31: cup-shaped element
50: Printed Circuit L: Operating Liquid / Fluid

Claims (12)

An optical type turbidity sensor (1)
And a casing (5) for accommodating the light emitting means (6) and the light receiving means (8)
The light emitting means 6 and the light receiving means 8 are provided on the second side 12 of the casing opposite the first side 10 and receive the light ray R1 from the light emitting means 6 Arranged side by side on the same first side (10) of said casing (5) opposite said reflective surface (11) and arranged to receive and reflect said light rays towards the light receiving means (8) Wherein the casing comprises first and second substantially cylindrical elements, the first substantially cylindrical element being concentrically fitted in a second substantially cylindrical element, each recess facing in the same direction, the second substantially The bottom wall 32 of the cylindrical element defines a first side of the casing and is provided on the opposite side to the first substantially cylindrical element and extends at a predetermined distance from the bottom wall and on the same first side of the casing Heading Optical-type turbidity sensor including a bridge member defining a second side of the frame, a casing consisting of at least one pair of opposite side members in the device. 2. A device according to claim 1, characterized in that said light emitting means (6) and light receiving means (8) are arranged side by side under the same lens shaped transparent portion (15) of said first side of said casing , Optical type turbidity sensor. 2. A device according to claim 1, characterized in that the reflecting surface (11) comprises means (18) for changing the distance (D) existing between the first side (10) of the casing and the reflecting surface (11) Wherein the turbidity sensor is operatively coupled. 2. A device according to claim 1, wherein said light emitting means and said light receiving means are arranged side by side on the same side of a printed circuit interposed between a bottom wall of a second substantially cylindrical element and a corresponding bottom wall of a first substantially cylindrical element Each of the diodes. The optical type turbidity sensor according to claim 1, wherein the temperature detecting element is also provided on the side of the light emitting means and the light receiving means on the first side of the casing. 4. The apparatus of claim 3, wherein the means for changing the distance between the reflective surface and the first side of the casing is a screw means; Wherein the reflective surface is formed on one side of a disk provided with a thread forming shank engaged with a thread forming sheet formed through a second side of the casing. 5. The device of claim 4, wherein said first and second substantially cylindrical elements are made of synthetic plastic material and are integrally snapped together by respective side walls (60, 61) thereof; A connector (65) connected to the printed circuit (50) by a plurality of electrically conductive shanks (66) inserted into the printed circuit and mounted through a first substantially cylindrical element, the connector comprising a first substantially cylindrical element Is formed integrally in the concave portion of the optical type turbidity sensor. 6. A device according to claim 5, characterized in that the light emitting means (6), the light receiving means (8) and the temperature detecting element (70) are arranged below the transparent part (15) The optical type turbidity sensor is provided in the same printed circuit (50). An optical type turbidity sensor (1)
And a casing (5) for accommodating the light emitting means (6) and the light receiving means (8)
The light emitting means 6 and the light receiving means 8 are provided on the second side 12 of the casing opposite the first side 10 and receive the light ray R1 from the light emitting means 6 Arranged side by side on the same first side (10) of said casing (5) opposite said reflective surface (11) and arranged to receive and reflect said light rays towards the light receiving means (8) Wherein the casing comprises first and second substantially cylindrical elements, the first substantially cylindrical element being concentrically fitted in a second substantially cylindrical element, each recess being oriented in the same direction, the optical type turbidity sensor . 10. A device according to claim 9, characterized in that the light emitting means (6) and the light receiving means (8) are arranged side by side under the same lens shaped transparent portion (15) of the first side of the casing , Optical type turbidity sensor. 11. A device according to claim 10, characterized in that the reflecting surface (11) comprises means (18) for changing the distance (D) existing between the first side (10) of the casing and the reflecting surface (11) Wherein the turbidity sensor is operatively coupled. 12. The apparatus of claim 11, wherein the means changes the distance between the reflective surface and the first side of the casing; Wherein the reflective surface is formed on one side of a disk provided with a thread forming shank engaged with a thread forming sheet formed through a second side of the casing.

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